CN211652514U - Underground water real-time monitoring device based on GIS platform - Google Patents

Abstract

The utility model discloses a groundwater real-time supervision device based on GIS platform, the power distribution box comprises a box body, there are two baffles in the inside of box, divide into first cavity with the box, second cavity and third cavity, first cavity and third cavity upper end are sealed, can take out in the first cavity and insert a plurality of drawers, there is the pole setting in the inside bottom of second cavity, the cover has rather than sliding connection's sleeve in the pole setting, threaded connection has little bolt on the sleeve, telescopic outer wall has GIS platform equipment, the outer wall from the top down of third cavity is fixed with the inlet tube, backup pad and drain pipe, inlet tube and drain pipe all communicate with the inside of third cavity. The device removes conveniently, can save space when not using and place, and make full use of solar energy power supply utilizes renewable resources, and other instruments that groundwater monitoring was used also can place in the device, conveniently carry, and the function is various, can carry out turbidity monitoring to groundwater effective stirring, and monitoring effect is better, utilizes GIS platform, convenient to use.

Description

Underground water real-time monitoring device based on GIS platform

Technical Field

The utility model relates to a groundwater monitoring technology field specifically is a groundwater real-time supervision device based on GIS platform.

Background

An IS system, namely a geographic information system, IS a subject developed along with the development of geographic science, computer technology, remote sensing technology and information science, the geographic information system IS an integration which IS formed by organizing computer hardware, software, geographic data and system management personnel and IS used for efficiently acquiring, storing, updating, operating, analyzing and displaying geographic information in any form, a groundwater real-time monitoring device based on a GIS platform can effectively monitor underground water quality in real time and has higher practicability, the existing groundwater real-time monitoring device based on the GIS platform can only monitor the turbidity of underground water once and cannot effectively and uniformly mix water quality during monitoring, the whole device IS inconvenient to move, other tools required for monitoring need still need to be carried additionally, the use IS inconvenient, the function IS single, and solar energy cannot be effectively utilized simultaneously, the resources are wasted, and the arrangement occupies a larger space when the device is not used.

SUMMERY OF THE UTILITY MODEL

For solving the defect that prior art exists, the utility model provides a groundwater real-time supervision device based on GIS platform.

In order to solve the technical problem, the utility model provides a following technical scheme:

the utility model relates to a real-time groundwater monitoring device based on a GIS platform, which comprises a box body, wherein two baffles are fixed inside the box body, the box body is divided into a first cavity, a second cavity and a third cavity, the upper ends of the first cavity and the third cavity are closed, the upper end of the second cavity is opened, a plurality of drawers are inserted into the first cavity in a drawing way, the bottom end of the inside of the second cavity is fixed with a vertical rod, the vertical rod is sleeved with a sleeve which is connected with the vertical rod in a sliding way, a small bolt is connected with the sleeve in a threaded way, a GIS platform device is fixed on the outer wall of the sleeve, a water inlet pipe, a support plate and a drain pipe are fixed on the outer wall of the third cavity from top to bottom, the water inlet pipe and the drain pipe are both communicated with the inside of the third cavity, valves are both arranged on the water inlet pipe and the drain pipe, a motor is fixed on the upper end of the support, the improved solar turbidimeter comprises a screw rod, and is characterized in that a plurality of stirring rods are radially fixed on the screw rod, the stirring rods and the screw rod are arranged inside a third cavity, an optical turbidimeter is arranged on the third cavity, a first button, a second button and a battery are fixed at the left end of a box body, two connecting blocks are fixed on the left side of the upper end of the box body, a long bolt connected with the connecting blocks in a sliding and rotating mode is inserted into the connecting blocks, a solar cell panel is fixed on the long bolt, a nut is connected with the long bolt in a threaded mode, four wheel carriers are fixed at the lower end of the box body, wheels are arranged on each wheel carrier, a transverse plate is fixed on one of the wheel carriers, and a large.

Preferably, GIS platform equipment, first button, second button, solar cell panel, optical turbidimeter and motor all with battery electric connection, first button and GIS platform equipment and optical turbidimeter electric connection, second button and motor electric connection, GIS platform equipment and optical turbidimeter signal connection.

Preferably, the wheel is a solid rubber wheel.

Preferably, the box body and the drawer are made of transparent plastic materials.

Preferably, the nut, the connecting block and the long bolt are all made of stainless steel materials.

Preferably, the length of the vertical rod is greater than the height of the second cavity, and the level height of the uppermost end of the vertical rod is the same as that of the long bolt.

Preferably, the rightmost end of the solar cell panel is arranged on the left side of the rightmost end of the box body.

Preferably, the optical turbidimeter is located in the middle of the third cavity.

Preferably, the diameter of the wheel is not less than 40 cm.

The utility model has the advantages that: this kind of groundwater real-time supervision device based on GIS platform, it is convenient to remove, can save space when not using and place, make full use of solar energy power supply utilizes renewable resources, resources are saved, environmental protection, other instruments that groundwater monitoring was used also can place in the device, conveniently carry, the function is various, can carry out turbidity monitoring to groundwater effective stirring, and monitoring effect is better, utilizes the GIS platform, and it is more convenient to use.

Drawings

The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention, and together with the description serve to explain the invention and not to limit the invention. In the drawings:

fig. 1 is a schematic structural diagram of a real-time groundwater monitoring device based on a GIS platform of the present invention;

FIG. 2 is a schematic view of the working state structure of the real-time groundwater monitoring device based on the GIS platform of the present invention;

fig. 3 is the utility model relates to a box and solar cell panel's overlook schematic structure diagram of groundwater real-time supervision device based on GIS platform.

In the figure: the device comprises a water drainage pipe 1, a valve 2, a wheel frame 3, wheels 4, a box body 5, a first cavity 5-1, a second cavity 5-2, a third cavity 5-3, a baffle 6, GIS platform equipment 7, a large bolt 8, a transverse plate 9, a first button 10, a second button 11, a battery 12, a drawer 13, a nut 14, a connecting block 15, a long bolt 16, a solar cell panel 17, an upright rod 18, a stirring rod 19, a water inlet pipe 20, an optical turbidimeter 21, a motor 22, a supporting plate 23, a screw rod 24, a sleeve 25 and a small bolt 26.

Detailed Description

The preferred embodiments of the present invention will be described in conjunction with the accompanying drawings, and it will be understood that they are presented herein only to illustrate and explain the present invention, and not to limit the present invention.

Example (b): as shown in figures 1, 2 and 3, the utility model relates to a groundwater real-time monitoring device based on GIS platform, which comprises a box body 5, two baffles 6 are fixed in the box body 5, the box body 5 is divided into a first cavity 5-1, a second cavity 5-2 and a third cavity 5-3, the upper ends of the first cavity 5-1 and the third cavity 5-3 are sealed, the upper end of the second cavity 5-2 is open, a plurality of drawers 13 are inserted in the first cavity 5-1 in a drawing manner, a vertical rod 18 is fixed at the bottom end in the second cavity 5-2, a sleeve 25 connected with the vertical rod in a sliding manner is sleeved on the vertical rod 18, a small bolt 26 is connected with the sleeve 25 in a threaded manner, a GIS platform device 7 is fixed on the outer wall of the sleeve 25, and a water inlet pipe 20 is fixed on the outer wall of the third cavity 5-3 from top to bottom, The solar water heater comprises a supporting plate 23 and a water drainage pipe 1, wherein the water inlet pipe 20 and the water drainage pipe 1 are communicated with the inside of a third cavity 5-3, valves 2 are arranged on the water inlet pipe 20 and the water drainage pipe 1, a motor 22 is fixed at the upper end of the supporting plate 23, a screw rod 24 is fixed at the left end of a shaft of the motor 22, a plurality of stirring rods 19 are radially fixed on the screw rod 24, the stirring rods 19 and the screw rod 24 are arranged in the third cavity 5-3, an optical turbidimeter 21 is arranged on the third cavity 5-3, a first button 10, a second button 11 and a battery 12 are fixed at the left end of a box body 5, two connecting blocks 15 are fixed at the left side of the upper end of the box body 5, a long bolt 16 connected with the connecting blocks in a sliding and rotating mode is inserted into the connecting blocks 15, a solar cell panel 17 is fixed on the long bolt 16, and a nut 14, the lower end of the box body 5 is fixedly provided with four wheel frames 3, each wheel frame 3 is provided with a wheel 4, one wheel frame 3 is fixedly provided with a transverse plate 9, and the transverse plate 9 is in threaded connection with a large bolt 8.

GIS platform equipment 7, first button 10, second button 11, solar cell panel 17, optical turbidimeter 21 and motor 22 all with battery 12 electric connection, first button 10 and GIS platform equipment 7 and optical turbidimeter 21 electric connection, second button 11 and motor 22 electric connection, GIS platform equipment 7 and optical turbidimeter 21 signal connection.

The wheel 4 is a solid rubber wheel.

The box body 5 and the drawer 13 are made of transparent plastic materials.

The nut 14, the connecting block 15 and the long bolt 16 are all made of stainless steel materials.

The length of the upright rod 18 is larger than the height of the second cavity 5-2, and the level height of the uppermost end of the upright rod 18 is the same as that of the long bolt 16.

The rightmost end of the solar cell panel 17 is arranged on the left side of the rightmost end of the box body 5.

The optical turbidimeter 21 is arranged in the middle of the third cavity 5-3.

The diameter of the wheel 4 is not less than 40 cm.

The working principle is as follows:

because two baffles 6 are fixed inside the box body 5, the box body 5 is divided into a first cavity 5-1, a second cavity 5-2 and a third cavity 5-3, the upper ends of the first cavity 5-1 and the third cavity 5-3 are closed, the upper end of the second cavity 5-2 is open, a plurality of drawers 13 can be inserted into the first cavity 5-1 in a drawing way, an upright post 18 is fixed at the bottom end inside the second cavity 5-2, a sleeve 25 which is connected with the upright post 18 in a sliding way is sleeved on the upright post 18, a small bolt 26 is connected on the sleeve 25 in a threaded way, a GIS platform device 7 is fixed on the outer wall of the sleeve 25, a water inlet pipe 20, a support plate 23 and a water outlet pipe 1 are fixed on the outer wall of the third cavity 5-3 from top to bottom, the water inlet pipe 20 and the water outlet pipe 1 are both communicated with the inside of the third cavity 5-3, valves 2 are, a motor 22 is fixed at the upper end of a supporting plate 23, a screw rod 24 is fixed at the left end of a shaft of the motor 22, a plurality of stirring rods 19 are radially fixed on the screw rod 24, the stirring rods 19 and the screw rod 24 are arranged in a third cavity 5-3, an optical turbidimeter 21 is arranged on the third cavity 5-3, a first button 10, a second button 11 and a battery 12 are fixed at the left end of the box body 5, two connecting blocks 15 are fixed at the left end of the upper end of the box body 5, a long bolt 16 connected with the connecting blocks 15 in a sliding and rotating manner is inserted into the connecting blocks 15, a solar cell panel 17 is fixed on the long bolt 16, a nut 14 is connected with the long bolt 16 in a threaded manner, four wheel carriers 3 are fixed at the lower end of the box body 5, wheels 4 are arranged on each wheel carrier 3, a transverse plate 9 is fixed on one wheel carrier 3, a large bolt 8 is connected with the transverse plate 9 in a threaded, The solar cell panel 17, the optical turbidimeter 21 and the motor 22 are electrically connected with the battery 12, the first button 10 is electrically connected with the GIS platform device 7 and the optical turbidimeter 21, the second button 11 is electrically connected with the motor 22, the GIS platform device 7 is in signal connection with the optical turbidimeter 21, when the device is used, the device is moved to a position where underground water needs to be pumped, the large bolt 8 is rotated to prevent the device from moving, the long bolt 16 is rotated to enable the solar cell panel 17 to be at a proper angle for power generation, meanwhile, the solar cell panel is locked by the nut 14, the sleeve 25 is slid, the GIS platform device 7 is positioned in a visible range, the sleeve 25 is locked by the small bolt 26, the first button 10 is pressed, the GIS platform device 7 and the optical turbidimeter 21 work, the valve 2 on the water inlet pipe 20 is opened, the underground water needing to be monitored is added into the third cavity 5-3 through the water inlet, the GIS platform equipment 7 is monitored in real time, the monitoring result is fed back to the GIS platform equipment 7 to be displayed, when underground water in the third cavity 5-3 forms sediment which is not beneficial to monitoring, the second button 11 is pressed, the motor 22 works, the stirring rod 19 and the screw rod 24 stir the underground water in multiple dimensions, the monitoring effect is more accurate and objective, the valve 2 on the drain pipe 1 can be opened, the underground water is discharged, water circulation is formed, real-time monitoring is carried out, the drawer 13 can contain other tools, the functions are various and the use is convenient, the solar panel 17 converts solar energy into electric energy to supply power to the equipment, renewable resources are fully utilized, resources are saved, the environment is protected, after the use is finished, the underground water in the third cavity 5-3 is discharged, the small bolt 26 sliding sleeve 25 is loosened, the GIS platform equipment 7 is placed into the second cavity 5-2, and the nut 14 is loosened, place solar cell panel 17 level on box 5, effectively practice thrift and place the space, box 5 and drawer 13 are formed by transparent plastic material preparation, and the quality is light, and is with low costs, can the condition in the real-time observation box 5 simultaneously, whole device resources are saved, environmental protection, convenient to use, the function is various, and the reliability is high, and the practicality is strong.

In the description of the present invention, it is to be understood that the terms "coaxial", "bottom", "one end", "top", "middle", "other end", "upper", "one side", "top", "inner", "front", "center", "both ends", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplicity of description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed and operated in a particular orientation, and therefore, should not be construed as limiting the present invention.

Furthermore, the terms "first", "second", "third", "fourth" are used for descriptive purposes only and are not to be construed as indicating or implying a relative importance or implicitly indicating the number of technical features indicated, whereby the features defined as "first", "second", "third", "fourth" may explicitly or implicitly include at least one such feature.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "disposed," "connected," "fixed," "screwed" and the like are to be construed broadly, e.g., as meaning fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through an intermediate medium, and may be connected through the inside of two elements or in an interaction relationship between two elements, unless otherwise specifically defined, and the specific meaning of the above terms in the present invention will be understood by those skilled in the art according to specific situations.

Finally, it should be noted that: although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or equivalents may be substituted for elements thereof. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (9)

1. A real-time underground water monitoring device based on a GIS platform comprises a box body (5), wherein two baffle plates (6) are fixed inside the box body (5) to divide the box body (5) into a first cavity (5-1), a second cavity (5-2) and a third cavity (5-3), the upper ends of the first cavity (5-1) and the third cavity (5-3) are sealed, the upper end of the second cavity (5-2) is open, a plurality of drawers (13) can be inserted into the first cavity (5-1) in a drawing mode, a vertical rod (18) is fixed at the bottom end inside the second cavity (5-2), a sleeve (25) which is connected with the vertical rod in a sliding mode is sleeved on the vertical rod (18), a small bolt (26) is connected to the sleeve (25) in a threaded mode, GIS platform equipment (7) is fixed on the outer wall of the sleeve (25), the outer wall of the third cavity (5-3) is fixed with a water inlet pipe (20), a support plate (23) and a water discharge pipe (1) from top to bottom, the water inlet pipe (20) and the water discharge pipe (1) are communicated with the inside of the third cavity (5-3), valves (2) are arranged on the water inlet pipe (20) and the water discharge pipe (1), a motor (22) is fixed at the upper end of the support plate (23), a screw rod (24) is fixed at the left end of the shaft of the motor (22), a plurality of stirring rods (19) are fixed on the screw rod (24) along the radial direction, the stirring rods (19) and the screw rod (24) are arranged inside the third cavity (5-3), an optical turbidimeter (21) is arranged on the third cavity (5-3), a first button (10), a second button (11) and a battery (12) are fixed at the left end of the box body (5), the solar energy power generation device is characterized in that two connecting blocks (15) are fixed on the left side of the upper end of the box body (5), long bolts (16) connected with the connecting blocks in a sliding and rotating mode are inserted into the connecting blocks (15), solar cell panels (17) are fixed on the long bolts (16), nuts (14) are connected with the long bolts (16) in a threaded mode, four wheel carriers (3) are fixed at the lower end of the box body (5), wheels (4) are arranged on each wheel carrier (3), a transverse plate (9) is fixed on one wheel carrier (3), and large bolts (8) are connected with the transverse plate (9) in a threaded mode.

2. A GIS platform based real-time monitoring device of groundwater according to claim 1, wherein: GIS platform equipment (7), first button (10), second button (11), solar cell panel (17), optical turbidimeter (21) and motor (22) all with battery (12) electric connection, first button (10) and GIS platform equipment (7) and optical turbidimeter (21) electric connection, second button (11) and motor (22) electric connection, GIS platform equipment (7) and optical turbidimeter (21) signal connection.

3. A GIS platform based real-time monitoring device of groundwater according to claim 1, wherein: the wheels (4) are solid rubber wheels.

4. A GIS platform based real-time monitoring device of groundwater according to claim 1, wherein: the box body (5) and the drawer (13) are made of transparent plastic materials.

5. A GIS platform based real-time monitoring device of groundwater according to claim 1, wherein: the nut (14), the connecting block (15) and the long bolt (16) are all made of stainless steel materials.

6. A GIS platform based real-time monitoring device of groundwater according to claim 1, wherein: the length of the vertical rod (18) is larger than the height of the second cavity (5-2), and the level height of the uppermost end of the vertical rod (18) is the same as that of the long bolt (16).

7. A GIS platform based real-time monitoring device of groundwater according to claim 1, wherein: the rightmost end of the solar cell panel (17) is arranged on the left side of the rightmost end of the box body (5).

8. A GIS platform based real-time monitoring device of groundwater according to claim 1, wherein: the optical turbidimeter (21) is arranged in the middle of the third cavity (5-3).

9. A GIS platform based real-time monitoring device of groundwater according to claim 1, wherein: the diameter of the wheel (4) is not less than 40 cm.

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